Radiation irradiating apparatus and radiation dose management system

ABSTRACT

A radiation irradiating apparatus includes a processing circuitry. The processing circuitry acquires a past cumulative dose distribution associated with patient identifying information, from a storage that is storable a cumulative dose distribution. The processing circuitry calculates a first cumulative dose distribution and a second cumulative dose distribution during a radiation irradiation to a patient associated with the patient identifying information, the first cumulative dose distribution being a cumulative dose distribution, the second cumulative dose distribution being generated by adding the first cumulative dose distribution to the past cumulative dose distribution. The processing circuitry displays, on a display, at least one of the first and second cumulative dose distributions during the radiation irradiation.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a divisional Application of U.S. Application Ser.No. 16/237,052, filed Dec. 31, 2018, which is a divisional Applicationof U.S. Application Ser. No. 14/883,930, filed Oct. 15, 2015, which isbased upon and claims the benefit of priority from Japanese PatentApplication No. 2014-215308, filed on Oct. 22, 2014, the entire contentsof which are incorporated herein by reference.

FIELD

An embodiment as an aspect of the present invention relates to aradiation irradiating apparatus capable of displaying a cumulative dosedistribution, and a radiation dose management system.

BACKGROUND

At present, the U.S., Europe and therearound perceive, as problems,increase in exposure due to radiological image examinations. Customershave a problem to reduce exposure to patients. The total dose ofAmerican citizens has increased six times as much as that in 1980. TheAmerican Association of Physicists in Medicine has warned medicaldoctors of not executing unnecessary radiological image examinations.American medical technologists have been educated to perform lower-doseexaminations.

In recent years, a dose tracking system (DTS) has been developed thatvisualizes a cumulative dose (exposed dose) due to radiation irradiationduring application of a radiation irradiating manipulation (anexamination (imaging), therapy, surgery and the like which areaccompanied by radiation irradiation) to a patient. This systemsequentially (in real time) displays the cumulative dose totalized fromthe start of the radiation irradiating manipulation to the present time.

During application of a further radiation irradiating manipulation to apatient having already been subjected to a radiation irradiatingmanipulation through a conventional DTS, the total cumulative dosesometimes exceeds a threshold even though the single cumulative dosedoes not exceeds a threshold for a single radiation irradiatingmanipulation. The single cumulative dose is a cumulative dose to besequentially calculated during the radiation irradiating manipulationunder execution. The total cumulative dose is a cumulative dosecalculated by adding the current, single cumulative dose to thecumulative dose due to past radiation irradiating manipulations.

Excess of the total cumulative dose above the threshold causes apossibility of following occurrence of erythema on the skin of apatient, which is radiodermatitis.

There is a problem in that displaying only one of the single cumulativedose and the total cumulative dose is insufficient to monitor thecumulative doses during execution of a radiation irradiatingmanipulation. However, this problem itself has not been identified froma conventional viewpoint. Consequently, there is no technique toeffectively display both of the single cumulative dose and the totalcumulative dose.

BRIEF DESCRIPTION OF THE DRAWINGS

In accompanying drawings,

FIG. 1 is a schematic diagram showing a configuration of a radiationirradiating apparatus according to a present embodiment;

FIG. 2 is a diagram showing a configuration example of a part of aradiation irradiator in the case where the radiation irradiatingapparatus is an X-ray diagnostic apparatus;

FIG. 3 is a diagram showing an example of data on a cumulative dosedistribution;

FIG. 4 is a diagram for showing details of the data on the cumulativedose distribution;

FIG. 5 is a block diagram showing functions of the radiation irradiatingapparatus according to the present embodiment;

FIG. 6 is a diagram showing an example of data on a past added dosedistribution;

FIG. 7 is a diagram showing a display screen of a single cumulative dosedistribution and a total cumulative dose distribution in an initialstate;

FIG. 8 is a diagram showing a first display screen of the singlecumulative dose distribution and the total cumulative dose distributionthat are sequentially calculated during a radiation irradiatingmanipulation under execution;

FIG. 9 is a diagram showing a second display screen of the singlecumulative dose distribution and the total cumulative dose distributionthat are sequentially calculated during a radiation irradiatingmanipulation under execution;

FIG. 10 is a diagram showing a third display screen of the singlecumulative dose distribution and the total cumulative dose distributionthat are sequentially calculated during a radiation irradiatingmanipulation under execution;

FIG. 11 is a diagram showing a fourth display screen of the singlecumulative dose distribution and the total cumulative dose distributionthat are sequentially calculated during a radiation irradiatingmanipulation under execution;

FIG. 12 is a diagram showing a fifth display screen of the singlecumulative dose distribution and the total cumulative dose distributionthat are sequentially calculated during a radiation irradiatingmanipulation under execution;

FIGS. 13 and 14 are diagrams showing a sixth display screen of thesingle cumulative dose distribution and the total cumulative dosedistribution that are sequentially calculated during a radiationirradiating manipulation under execution;

FIG. 15 is a schematic diagram showing a configuration of a radiationdose management system according to a present embodiment;

FIG. 16 is a diagram showing an example of data on a cumulative dosedistribution;

A set of FIGS. 17A and 17B is a block diagram showing functions of theradiation dose management system according to the present embodiment;and

A set of FIGS. 18A and 18B is a flowchart showing operations of theradiation dose management system according to the present embodiment.

DETAILED DESCRIPTION

A radiation irradiating apparatus and a radiation dose management systemaccording to a present embodiment are described with reference to theaccompanying drawings.

To solve the above-described problems, the present embodiment providesthe radiation irradiating apparatus including a processing circuitryconfigured to: acquire a past cumulative dose distribution associatedwith patient identifying information, from a storage that is storable acumulative dose distribution; calculate a first cumulative dosedistribution and a second cumulative dose distribution during aradiation irradiation to a patient associated with the patientidentifying information, the first cumulative dose distribution being acumulative dose distribution, the second cumulative dose distributionbeing generated by adding the first cumulative dose distribution to thepast cumulative dose distribution; and display, on a display, at leastone of the first and second cumulative dose distributions during theradiation irradiation.

To solve the above-described problems, the present embodiment providesthe radiation dose management system including a processing circuitryconfigured to: acquire a past cumulative dose distribution associatedwith required patient identifying information, from a storage that isstorable a plurality of cumulative dose distributions by a plurality ofradiation irradiating apparatuses performing radiation irradiations;calculate a first cumulative dose distribution and a second cumulativedose distribution during a radiation irradiation to a patient associatedwith the required patient identifying information, the first cumulativedose distribution being a cumulative dose distribution, the secondcumulative dose distribution being generated by adding the firstcumulative dose distribution to the past cumulative dose distribution;and display, on a display, at least one of the first and secondcumulative dose distributions during the radiation irradiation.

Radiation Irradiating Apparatus

FIG. 1 is a schematic diagram showing a configuration of a radiationirradiating apparatus according to a present embodiment.

FIG. 1 shows the radiation irradiating apparatus 10 according to thepresent embodiment. The radiation irradiating apparatus 10 may be, forexample, any of radiation diagnostic apparatuses (radiation examapparatuses), such as X-ray diagnostic apparatuses (angiographyapparatuses, X-ray fluoroscopic imaging apparatuses, etc.) and X-raycomputed tomography (CT) apparatuses, and radiation therapeuticapparatuses, such as gamma knives.

The radiation irradiating apparatus 10 has a configuration of a typicalcomputer. The radiation irradiating apparatus 10 roughly includes basichardware, which is a processing circuitry 11, a storage 12, an operationdevice 13, a display 14, a communication device 15 and the like, aradiation irradiator 16, and a cumulative dose distribution database(DB) 17. The processing circuitry 11 is mutually connected to each ofthe hardware configuration elements, which configure the radiationirradiating apparatus 10, via a bus as a common signal transmissionpath.

The processing circuitry 11 reads various control programs stored in thestorage 12 and performs various operations while integrally controllingprocessing operations in the elements 12 to 17.

The processing circuitry 11 means any one of dedicated or generalcentral processing unit (CPU) and a micro processor unit (MPU), anapplication specific integrated circuit (ASIC), and a programmable logicdevice. The programmable logic device may be, for example, any one of asimple programmable logic device (SPLD), a complex programmable logicdevice (CPLD), a field programmable gate array (FPGA) and the like. Theprocessing circuitry 11 reads programs stored in the storage 12 ordirectly implemented in the processing circuitry 11 and executes theseprograms to thereby achieve functions 111 to 117 shown in FIG. 5.

The processing circuitry 11 may be a single circuit or a combination ofseparate circuits. In the latter case, the storage 12, which stores theprograms, may be separately provided for each of the circuits.Alternatively, a single storage 12 may store the programs correspondingto the functions of the multiple circuits.

The storage 12 includes a memory and a hard disc drive (HDD). Thestorage 12 stores data required to execute the control programs used inthe processing circuitry 11, and various types of data.

The operation device 13 includes a keyboard and a mouse. When anoperator operates the operation device 13, this unit 13 generates anoperation signal corresponding to the operation, and outputs theoperation signal to the processing circuitry 11. Alternatively, a touchpanel that integrally includes this operation device 13 and the display14 may be provided.

The display 14 includes a display unit, such as a liquid crystal display(LCD). The display 14 displays various operation screens on the displayunit according to instructions from the processing circuitry 11.

The communication device 15 includes a connector in conformity with aparallel connection specification or a serial connection specification.The communication device 15 transmits and receives information to andfrom external apparatuses on networks.

The radiation irradiator 16 includes a structure (not shown) foremitting radiation. The radiation irradiator 16 is a device thatirradiates a patient with radiation under control of the processingcircuitry 11. In the case where the radiation irradiating apparatus 10is an X-ray diagnostic apparatus, the radiation irradiator 16 includestypical structures, such as a high voltage generator, an X-ray source(X-ray tube), an X-ray detector, a C-arm, and a bed. In the case wherethe radiation irradiating apparatus 10 is an X-ray CT apparatus, theradiation irradiator 16 includes typical structures, such as a highvoltage generator, an X-ray source, an X-ray detector, a rotation unit,and a bed. In the case where the radiation irradiating apparatus 10 is aradiation therapeutic apparatus, the radiation irradiator 16 includestypical structures, such as a high voltage generator, a radiationsource, a rotation unit, and a bed.

FIG. 2 is a diagram showing a configuration example of a part of theradiation irradiator in the case where the radiation irradiatingapparatus 10 is an X-ray diagnostic apparatus.

FIG. 2 shows a part of the radiation irradiator 16 and the display 14.The radiation irradiator 16 includes an X-ray tube 31, an X-ray detector32, a C-arm 33, and a table-top 34.

The X-ray tube 31 generates X-rays through application of a high voltage(tube voltage) by a high voltage generator, not shown. The X-ray tube 31is attached to one end of the C-arm 33. The X-ray detector 32 isattached to the other end of the C-arm 33 opposite to the X-ray tube 31.The example is herein described where the radiation irradiator 16includes the C-arm 33, and this C-arm 33 causes the X-ray tube 31 andthe X-ray detector 32 to integrally operate. However, the technique isnot limited to this case. For example, a configuration may be adoptedwhere the radiation irradiator 16 does not include C-arm 33 and causesthe X-ray tube 31 and the X-ray detector 32 to operate separately fromeach other instead.

The X-ray detector 32 is a flat panel detector that includestwo-dimensionally arranged detection elements (pixels) for directly orindirectly converting incident X-rays into electric charges. However,the X-ray detector 32 may include an image intensifier (I. I.) and a TVcamera. During imaging through X-ray irradiation, an object (patient) Pis arranged between the X-ray tube 31 and the X-ray detector 32 in astate of being mounted on the table-top 34.

The C-arm 33 is supported by a ceiling base 35 via a suspension arm 36so as to be rotatable under a predetermined limitation with respect toeach of X, Y and Z directions, which are orthogonal to each other, inorder to freely change the angle at which the patient P is irradiatedwith X-rays. The line passing from the X-ray focal point of the X-raytube 31 to the center of detection plane of the X-ray detector 32 isreferred to as an imaging axis. The imaging angle is typically definedas the angles at which the imaging axis intersects with the respectiveX, Y and Z directions. According to convention, the angles arerepresented as a first oblique position (RAO: right anterior obliqueposition), second oblique position (LAO: left anterior obliqueposition), third oblique position (LPO: left posterior oblique position)and fourth oblique position (RPO: right posterior oblique position).Typically, the Z direction is defined to coincide with the longitudinaldirection of the table-top 34.

Returning to the description with respect to FIG. 1, the cumulative dosedistribution DB 17 is a storage that includes an HDD and a memory. Thecumulative dose distribution DB 17 can store data on the cumulative dosedistribution that represents the distribution of three-dimensionalcumulative dose (mGy) accompanied by patient identifying information(patient ID) for identifying a patient and by execution time informationon past radiation irradiating manipulations (examinations (imaging),therapy and surgery through radiation irradiation). The cumulative dosedistribution is typically generated with respect to each radiationirradiating manipulation.

FIG. 3 is a diagram showing an example of data on the cumulative dosedistribution.

As shown in FIG. 3, the cumulative dose distribution DB 17 (shown inFIG. 1) can store multiple cumulative dose distributions wherecumulative doses in a model coordinate system are associated withrespective body surface positions of a three-dimensional human bodymodel. Each cumulative dose distribution is accompanied by the patientidentifying information contained in patient information and theexecution time information.

FIG. 3 shows the case where mapping of the cumulative doses to the bodysurface positions of the human body model is stored as the cumulativedose distribution. Alternatively, data on the human body model, and thecumulative doses on the body surface positions may be separately stored.Instead of the human body model, volume data that has already beengenerated and encompasses the entire patient may be used.

FIG. 4 is a diagram for showing details of the data on the cumulativedose distribution.

As shown in FIG. 4, the cumulative dose distribution in the human bodymodel coordinate system is based on the cumulative doses on the bodysurface positions (points) Q1 to Q6 in the human body model. The bodysurface positions Q1 to Q6 are associated with information on the Xcoordinate, Y coordinate, Z coordinate, and cumulative dose (mGy). Here,the X coordinate corresponds to the lateral direction of the patient.The Y coordinate corresponds to the ventrodorsad direction of thepatient. The Z coordinate corresponds to the body axis direction of thepatient. The cumulative doses on the body surface positions may beregistered separately from or together with the human body model. In thecase with no exposure dose (body surface positions Q1 to Q6), thecumulative dose is 0 mGy.

FIG. 5 is a block diagram showing functions of the radiation irradiatingapparatus 10 according to the present embodiment.

The processing circuitry 11 included in the radiation irradiatingapparatus 10 according to the present embodiment executes the programsto thereby cause the radiation irradiating apparatus 10 to function asan operation assisting function 111, a condition setting function 112, apast cumulative dose distribution acquiring function 113, a past addeddose distribution calculating function 114, a radiation irradiationexecuting function 115, a sequential cumulative dose distributioncalculating function 116, and a cumulative dose distribution registeringfunction 117. The description is made assuming that the functions 111 to117 function as software. Alternatively, all or some of the functions111 to 117 may be implemented as hardware in the radiation irradiatingapparatus 10.

The operation assisting function 111 is an interface between thefunctions 112 to 117 and the operation device 13 and display 14, and maybe a graphical user interface (GUI) or the like.

The condition setting function 112 sets the patient identifyinginformation (patient ID) based on an operation at the operation device13 through the operation assisting function 111. The patient ID is usedfor acquiring the past cumulative dose distributions pertaining to thepatient subjected to the radiation irradiating manipulation.Furthermore, the condition setting function 112 may set a periodcondition for acquiring only the cumulative dose distributions in aspecific period among all the past cumulative dose distributionspertaining to the patient subjected to the radiation irradiatingmanipulation.

The past cumulative dose distribution acquiring function 113 acquires(reads), from the cumulative dose distribution DB 17, the pastcumulative dose distributions associated with the patient identifyinginformation set by the condition setting function 112. When thecondition setting function 112 sets the period condition, the pastcumulative dose distribution acquiring function 113 acquires, from thecumulative dose distribution DB 17, the cumulative dose distributionsassociated with the patient identifying information set by the conditionsetting function 112 and with the execution time information within therange of the period condition.

For example, if patient identifying information “P1” is set by thecondition setting function 112, the past cumulative dose distributionacquiring function 113 acquires three past cumulative dose distributionsassociated with the patient identifying information “P1” from among thepast cumulative dose distributions shown in FIG. 3. If the patientidentifying information “P1” and a period condition “Jan. 1, 2013 toPresent” are set by the condition setting function 112, the pastcumulative dose distribution acquiring function 113 acquires two pastcumulative dose distributions that are associated with the patientidentifying information “P1” and are within the range of the periodcondition “Jan. 1, 2013 to Present” from among the past cumulative dosedistributions shown in FIG. 3.

The past added dose distribution calculating function 114 aligns, whenthe past cumulative dose distributions are acquired by the pastcumulative dose distribution acquiring function 113, the past cumulativedose distributions, and adds (or totalizes) the distributions withrespect to the body surface positions of the human body model, therebycalculating the data on a past added dose distribution pertaining to thepast radiation irradiating manipulations.

That is, when the past cumulative dose distributions are acquired by thepast cumulative dose distribution acquiring function 113, the past addeddose distribution calculating function 114 adds the past cumulativedoses with respect to the body surface positions, thereby calculatingthe data on the past added dose distribution pertaining to the pastradiation irradiating manipulations. In the case where one pastcumulative dose distribution is acquired by the past cumulative dosedistribution acquiring function 113, the past added dose distributioncalculating function 114 is unnecessary.

FIG. 6 is a diagram showing an example of data on the past added dosedistribution.

FIG. 6 shows the past added dose distribution. The past cumulative dosedistributions are aligned and added to acquire the past added dosedistribution. For example, FIG. 6 shows the distribution acquired byaligning and adding three cumulative dose distributions associated withthe patient identifying information “P1” shown in FIG. 3.

Returning to the description with reference to FIG. 5, when the pastadded dose distribution calculating function 114 aligns and adds thepast cumulative dose distributions acquired by the cumulative dosedistribution acquiring function 113, the function 114 may performweighted addition by multiplying the cumulative dose distributions byrespective coefficients (of a linear function, an exponential function,a logarithmic function, a combination thereof, etc.). The coefficientsare set so as to attach importance to radiation irradiation from whichshorter time has elapsed than radiation irradiation from which longertime has elapsed. In the case of therapeutic radiation irradiation, thecoefficients are set so as to consider the recovering degree of cellshaving been irradiated with radiation.

The radiation irradiation executing function 115 applies a radiationirradiating manipulation to the patient associated with the patientidentifying information set by the condition setting function 112. Here,in the case where the radiation irradiating apparatus 10 is an X-raydiagnostic apparatus or an X-ray CT apparatus, the radiation irradiationexecuting function 115 controls the operation of the radiationirradiator 16 to collect an image pertaining to the detection portion ofthe patient while emitting radiation. When the radiation irradiatingapparatus 10 is the X-ray diagnostic apparatus, the radiationirradiation executing function 115 sequentially generates each offluoroscopic images based on the X-rays having passed through thepatient, and displays the fluoroscopic images as a moving image. In thecase where the radiation irradiating apparatus 10 is a radiationtherapeutic apparatus, the radiation irradiation executing function 115controls the operation of the radiation irradiator 16 to irradiate atherapy target portion of the patient.

The sequential cumulative dose distribution calculating function 116cumulates, during execution of the radiation irradiating manipulation bythe radiation irradiation executing function 115, the exposure dosesuntil the present time, thereby calculating the cumulative dose. Thesequential cumulative dose distribution calculating function 116calculates the cumulative dose distribution that associates thecumulative doses with the body surface positions of the human bodymodel.

The sequential cumulative dose distribution calculating function 116 cansequentially (e.g. in real time) calculate, during execution of theradiation irradiating manipulation, the cumulative dose and thecumulative dose distribution. Alternatively, at any timing in executionof the radiation irradiating manipulation, the sequential cumulativedose distribution calculating function 116 can calculate the cumulativedose and the cumulative dose distribution. Any timing means, forexample, a timing designated by the operator. The case is hereinafterdescribed where the sequential cumulative dose distribution calculatingfunction 116 sequentially calculates the cumulative dose and thecumulative dose distribution during execution of the radiationirradiating manipulation.

The body surface position of the patient in the real coordinate systemis coordinate-transformed into the corresponding body surface positionin the human body model in the model coordinate system. Thistransformation allows the cumulative dose pertaining to the body surfaceposition of the patient in the real coordinate system to be consideredas the cumulative dose on the corresponding body surface position of thehuman body model. The sequential cumulative dose distributioncalculating function 116 includes a single cumulative dose distributioncalculating function 116 a, and a total cumulative dose distributioncalculating function 116 b.

The single cumulative dose distribution calculating function 116 asequentially calculates, as the single cumulative dose distribution, thecumulative dose distribution from the start of the radiation irradiatingmanipulation under execution to the present time during execution of theradiation irradiating manipulation. The single cumulative dosedistribution associates the cumulative doses from the start of theradiation irradiating manipulation under execution to the present timewith the body surface positions of the human body model.

The total cumulative dose distribution calculating function 116 bsequentially adds the single cumulative dose distribution calculated bythe single cumulative dose distribution calculating function 116 a tothe past added dose distribution calculated by the past added dosedistribution calculating function 114, during execution of the radiationirradiating manipulation. The total cumulative dose distributioncalculating function 116 b calculates the total cumulative dosedistribution to the present time from the start of the radiationirradiating manipulation pertaining to the latest cumulative dosedistribution among the past cumulative dose distributions. The totalcumulative dose distribution associates, with the body surface positionsof the human body model, the total cumulative doses to the present timefrom the start of the radiation irradiating manipulation pertaining tothe latest cumulative dose distribution among the past cumulative dosedistributions.

When the one past cumulative dose distribution is acquired by the pastcumulative dose distribution acquiring function 113, the totalcumulative dose distribution calculating function 116 b sequentiallyadds the single cumulative dose distribution calculated by the singlecumulative dose distribution calculating function 116 a to one pastcumulative dose distribution acquired by the past cumulative dosedistribution acquiring function 113, during execution of the radiationirradiating manipulation. The total cumulative dose distributioncalculating function 116 b calculates the total cumulative dosedistribution to the present time from the start of the radiationirradiating manipulation pertaining to the one past cumulative dosedistribution.

The sequential cumulative dose distribution calculating function 116displays, on the display 14, the single cumulative dose distribution andthe total cumulative dose distribution through the operation assistingfunction 111 during execution of the radiation irradiating manipulation.That is, the sequential cumulative dose distribution calculatingfunction 116 displays, on the display 14, the single cumulative dosedistribution at a timing in execution of the radiation irradiatingmanipulation while displaying, on the display 14, the total cumulativedose distribution at a timing in execution of the radiation irradiatingmanipulation. The sequential cumulative dose distribution calculatingfunction 116 sequentially displays both of the single cumulative dosedistribution and the total cumulative dose distribution during executionof the radiation irradiating manipulation (FIGS. 8 and 10 to 14), orswitches between sequential display of the single cumulative dosedistribution and the sequential display of the total cumulative dosedistribution (FIG. 9). That is, the sequential cumulative dosedistribution calculating function 116 sequentially calculates adistribution to be displayed that is at least one of the singlecumulative dose distribution and the total cumulative dose distribution,and sequentially displays the distribution, during execution of theradiation irradiating manipulation.

The sequential cumulative dose distribution calculating function 116 isable to sequentially display, on the display 14, the distribution to bedisplayed, and display, on the display 14, the fluoroscopic images as amoving image, the fluoroscopic images being generated by the X-raydiagnostic apparatus as the radiation irradiating apparatus 10.

Thus, the sequential cumulative dose distribution calculating function116 sequentially calculates both of the single cumulative dosedistribution and the total cumulative dose distribution, therebyallowing both of the single cumulative dose distribution and the totalcumulative dose distribution to be displayed in a juxtaposed manner. Thesequential cumulative dose distribution calculating function 116sequentially calculates both of the single cumulative dose distributionand the total cumulative dose distribution, thereby allowing one of thedistributions to be sequentially displayed in a switchable manner whileallowing the other distribution to be displayed immediately afterswitching to the other distribution.

FIG. 7 is a diagram showing a display screen of the single cumulativedose distribution and the total cumulative dose distribution in aninitial state.

A display screen DO shown in FIG. 7 contains the single cumulative dosedistribution and the total cumulative dose distribution before start ofthe radiation irradiating manipulation by the radiation irradiationexecuting function 115 (shown in FIG. 5) (in the initial state). Theradiation irradiating manipulation by the radiation irradiationexecuting function 115 has not been started yet. Accordingly, the singlecumulative dose distribution is only of the human body model. The totalcumulative dose distribution is the past added dose distribution inconsideration of the human body model. The total cumulative dosedistribution is provided with color attribute information (including atleast one of hue information, lightness information, and chromasaturation information) according to the degree of the total cumulativedose for each body surface position of the human body model.

The single cumulative dose distribution and the total cumulative dosedistribution in the initial state are each three-dimensional data.Consequently, when the distributions are displayed on the display screenD0, the distributions are displayed as three-dimensional images havingbeen subjected to a rendering process based on a freely selectedviewpoint. The freely selected viewpoint can be appropriately changed.

The display screen shown in FIG. 7 is an initial screen of a firstdisplay screen shown in FIG. 8. The initial screen of second to sixthdisplay screens shown in FIGS. 9 to 14 is the same.

FIG. 8 is a diagram showing a first display screen (screen displayed ina juxtaposed manner) of the single cumulative dose distribution and thetotal cumulative dose distribution that are sequentially calculatedduring the radiation irradiating manipulation under execution.

A display screen D1 shown in FIG. 8 contains the single cumulative dosedistribution and the total cumulative dose distribution that aresequentially displayed in a juxtaposed manner. The single cumulativedose distribution on the display screen D1 is sequentially updated. Theupdate allows the operator to sequentially view the cumulative dose fromthe start of the radiation irradiating manipulation under execution tothe present time. The total cumulative dose distribution on the displayscreen D1 is sequentially updated. The update allows the operator tosequentially view the cumulative dose to the present time from the pastradiation irradiating manipulations pertaining to the patient.

FIG. 9 is a diagram showing a second display screen (screen displayed ina switchable manner) of the single cumulative dose distribution and thetotal cumulative dose distribution that are sequentially calculatedduring the radiation irradiating manipulation under execution.

The display screen shown in FIG. 9 switches between a display screen D2for sequentially displaying the single cumulative dose distribution anda display screen D2′ for sequentially displaying the total cumulativedose distribution. The single cumulative dose distribution on thedisplay screen D2 is sequentially updated while the display screen D2 isdisplayed. The update allows the operator to sequentially view thecumulative dose from the start of the radiation irradiating manipulationunder execution to the present time. The total cumulative dosedistribution on the display screen D2′ is sequentially updated while thedisplay screen D2′ is displayed. The update allows the operator tosequentially view the cumulative dose to the present time from the pastradiation irradiating manipulations pertaining to the patient.

The display of the cumulative dose distribution is switched from thedisplay screen D2 to the display screen D2′ and from the display screenD2′ to the display screen D2 at a required timing. The switching timingmay be according to an operation through the operation device 13 (shownin FIG. 5), or be a timing when the cumulative dose reaches a threshold(a timing of an alarm sound). Alternatively, the switching timing may beaccording to a preset time interval.

FIG. 10 is a diagram showing a third display screen (zoom-in-and-outdisplay screen) of the single cumulative dose distribution and the totalcumulative dose distribution that are sequentially calculated during theradiation irradiating manipulation under execution.

A display screen D3 shown in FIG. 10 contains the single cumulative dosedistribution and the total cumulative dose distribution, one of which iszoomed in and sequentially displayed, and the other of which is zoomedout and sequentially displayed. For example, on the display screen D3,the single cumulative dose distribution is zoomed in and displayed whilethe total cumulative dose distribution is zoomed out and displayed. Thesingle cumulative dose distribution on the display screen D3 issequentially updated. The update allows the operator to sequentiallyview the cumulative dose from the start of the radiation irradiatingmanipulation under execution to the present time. The total cumulativedose distribution on the display screen D3 is sequentially updated. Theupdate allows the operator to sequentially view the cumulative dose tothe present time from the past radiation irradiating manipulationspertaining to the patient.

On the display screen D3 shown in FIG. 10, the single cumulative dosedistribution is zoomed in and displayed while the total cumulative dosedistribution is zoomed out and displayed. Alternatively, the object tobe zoomed in and displayed and the object to be zoomed out and displayedmay be replaced with each other. A configuration may be adopted that canfreely switch between the zoom-in display and the zoom-out display.

FIG. 11 is a diagram showing a fourth display screen (entire and partialdisplay screen) of the single cumulative dose distribution and the totalcumulative dose distribution that are sequentially calculated during theradiation irradiating manipulation under execution.

A display screen D4 shown in FIG. 11 contains the single cumulative dosedistribution and the total cumulative dose distribution, one of which issequentially displayed in its entirety, and the other of which issequentially displayed partially. For example, on the display screen D4,the entire single cumulative dose distribution is displayed while a partof the total cumulative dose distribution is displayed. The entiresingle cumulative dose distribution on the display screen D4 issequentially updated. The update allows the operator to sequentiallyview the cumulative dose from the start of the radiation irradiatingmanipulation under execution to the present time. The part of the totalcumulative dose distribution on the display screen D4 is sequentiallyupdated. The update allows the operator to sequentially view thecumulative dose to the present time from the past radiation irradiatingmanipulations pertaining to the patient.

On the display screen D4 shown in FIG. 11, the entire single cumulativedose distribution is displayed while the part of the total cumulativedose distribution is displayed. Alternatively, the object to bedisplayed in its entirety and the object to be displayed partially maybe replaced with each other. A configuration may be adopted that canfreely switch between the entire display and the partial display.

FIG. 12 is a diagram showing a fifth display screen (shaded and numericdisplay screen) of the single cumulative dose distribution and the totalcumulative dose distribution that are sequentially calculated during theradiation irradiating manipulation under execution.

On the display screen D5 shown in FIG. 12, one of the single cumulativedose distribution and the total cumulative dose distribution is shadedand sequentially displayed, and the maximum value of the otherdistribution is sequentially displayed in a numeric value. For example,on the display screen D5, the shade according to the single cumulativedose distribution and the maximum value are displayed, the maximum valuebeing among the total cumulative doses in the total cumulative dosedistribution. The shade according to the single cumulative dosedistribution on the display screen D5 is sequentially updated. Theupdate allows the operator to sequentially view the cumulative dose fromthe start of the radiation irradiating manipulation under execution tothe present time. The maximum value of the total cumulative doses on thedisplay screen D5 is sequentially updated. The update allows theoperator to sequentially view the maximum value of the cumulative doseto the present time from the past radiation irradiating manipulationspertaining to the patient.

On the display screen D5 shown in FIG. 12, the shaded single cumulativedose distribution is displayed while the maximum value of the totalcumulative dose is numerically displayed. Alternatively, the object tobe shaded and displayed and the object to be numerically displayed maybe replaced with each other. A configuration may be adopted that canfreely switch between the shaded display and the numeric display.

FIGS. 13 and 14 are diagrams showing a sixth display screen (overlaiddisplay screens) of the single cumulative dose distribution and thetotal cumulative dose distribution that are sequentially calculatedduring the radiation irradiating manipulation under execution.

The display screen D6 shown in FIGS. 13 and 14 contains the singlecumulative dose distribution and the total cumulative dose distributionwhich are sequentially displayed in different display patterns in anoverlaid manner. On body surface portions having single cumulative doseshigher than zero on the three-dimensional image (rendered image) of thesingle cumulative dose distribution, dots are set at intervals. The dotsare represented by the attribute information on colors according to thedegrees of the single cumulative doses on the dots (the average value ofsingle cumulative doses on the dots). As with the display screen D6shown in FIG. 13, dots assigned color attribute information on the basisof the single cumulative dose distribution are overlaid on thethree-dimensional image of the total cumulative dose distribution,thereby allowing the single cumulative dose distribution and the totalcumulative dose distribution to be displayed in an overlaid manner.

On the other hand, the body surface portions having single cumulativedoses higher than zero on the three-dimensional image of the singlecumulative dose distribution are hatched. The hatching is represented bythe attribute information on colors according to the degrees of thesingle cumulative doses on the hatching (the average value of singlecumulative doses on the hatching). As illustrated in the display screenD6 shown in FIG. 14, the hatching assigned color attribute informationon the basis of the single cumulative dose distribution is overlaid onthe three-dimensional image of the total cumulative dose distribution,thereby allowing the single cumulative dose distribution and the totalcumulative dose distribution to be displayed in an overlaid manner.

The single cumulative dose distribution on the display screen D6 issequentially updated. The update allows the operator to sequentiallyview the cumulative dose from the start of the radiation irradiatingmanipulation under execution to the present time. The total cumulativedose distribution on the display screen D6 is sequentially updated. Theupdate allows the operator to sequentially view the cumulative dose tothe present time from the past radiation irradiating manipulationspertaining to the patient.

Returning to the description with reference to FIG. 5, after theradiation irradiating manipulation by the radiation irradiationexecuting function 115 is finished, the cumulative dose distributionregistering function 117 assigns the patient identifying information andthe execution time information to the cumulative dose distribution(single cumulative dose distribution) calculated by the singlecumulative dose distribution calculating function 116 a of thesequential cumulative dose distribution calculating function 116, andregisters the distribution in the cumulative dose distribution DB 17.

The radiation irradiating apparatus 10 according to the presentembodiment effectively displays, on the display 14, at least one of thesingle cumulative dose distribution and the total cumulative dosedistribution pertaining to the patient during application of theradiation irradiating manipulation to the patient, thereby allowing theoperator, who is a medical doctor or a medical technician, to easilymonitor the single cumulative dose distribution and the total cumulativedose distribution during the application of the radiation irradiatingmanipulation to the patient.

The radiation irradiating apparatus 10 according to the presentembodiment effectively displays, on the display 14, at least one of thesingle cumulative dose distribution and the total cumulative dosedistribution during application of the radiation irradiatingmanipulation to the patient, thereby allowing the operator to easilydetermine an appropriate radiation irradiating direction so as toprevent portions having been irradiated with radiation from beingfurther irradiated, during the application of the radiation irradiatingmanipulation to the patient. Consequently, the radiation damage to thepatient can be alleviated. The radiation irradiating apparatus 10according to the present embodiment allows the operator to perform theradiation irradiating manipulation while verifying whether theapplication of the radiation during their radiation irradiatingmanipulation to the patient is appropriate or not through the display14.

Radiation Dose Management System

FIG. 15 is a schematic diagram showing a configuration of a radiationdose management system according to a present embodiment.

FIG. 15 shows the radiation dose management system 30 according to thepresent embodiment. The radiation dose management system 30 includes aradiation dose management apparatus 40, and multiple radiationirradiating apparatuses 50 (radiation irradiating apparatuses 50 a, 50b, . . . ). The radiation irradiating apparatuses 50 may be, forexample, any of radiation diagnostic apparatuses (radiation examapparatuses), such as X-ray diagnostic apparatuses and X-ray CTapparatuses, and radiation therapeutic apparatuses, such as gammaknives.

The radiation dose management apparatus 40 has a configuration of atypical computer. The radiation dose management apparatus 40 roughlyincludes basic hardware, which is a processing circuitry 41, a storage42, an operation device 43, a display 44 and a communication device 45,and a cumulative dose distribution DB 47. The processing circuitry 41 ismutually connected to each of the hardware configuration elements, whichconfigure the radiation dose management apparatus 40, via a bus as acommon signal transmission path.

The elements, from the processing circuitry 41 to the communicationdevice 45, have the same configurations and functions as those of therespective elements, from the processing circuitry 11 to thecommunication device 15, shown in FIG. 1. Consequently, the descriptionthereof is omitted.

As with the cumulative dose distribution DB 17 shown in FIG. 1, thecumulative dose distribution DB 47 is a storage that includes an HDD anda memory. The cumulative dose distribution DB 47 can store data on thecumulative dose distribution that represents the three-dimensionaldistribution of cumulative doses (mGy) accompanied by any of patientidentifying information (patient ID) for identifying a patient,execution time information on past radiation irradiating manipulations,and apparatus identifying information for identifying a radiationirradiating apparatus among the radiation irradiating apparatuses havingperformed the radiation irradiating manipulation (shown in FIG. 16). Thecumulative dose distribution is typically generated with respect to eachradiation irradiating manipulation.

Unlike the cumulative dose distribution DB 17 shown in FIG. 1, thecumulative dose distribution DB 47 can store data on multiple cumulativedose distributions that have been calculated by the respective radiationirradiating apparatuses 50 and transmitted from these apparatuses 50.

FIG. 16 is a diagram showing an example of data on the cumulative dosedistribution.

As shown in FIG. 16, the cumulative dose distribution DB 47 (shown inFIG. 15) can store multiple cumulative dose distributions wherecumulative doses in a human body model coordinate system are associatedwith respective body surface positions of the human body model. Eachcumulative dose distribution is accompanied by the patient identifyinginformation contained in the patient information, the execution timeinformation, and the apparatus identifying information. FIG. 16 showsthe case where mapping of the cumulative doses to the body surfacepositions of the human body model is stored as the cumulative dosedistribution. Alternatively, data on the human body model, and thecumulative doses on the body surface positions may be separately stored.

Returning to the description with reference to FIG. 15, each of theradiation irradiating apparatuses 50 has a configuration of a typicalcomputer. Each of the radiation irradiating apparatuses 50 roughlyincludes basic hardware, which is processing circuitry 51, a storage 52,an operation device 53, a display 54 and a communication device 55, anda radiation irradiator 56. The processing circuitry 51 is mutuallyconnected to each of the hardware configuration elements, whichconfigure the radiation irradiating apparatuses 50, via a bus as acommon signal transmission path.

The elements, from the processing circuitry 51 to the communicationdevice 55, have the same configurations and functions as those of therespective elements, from the processing circuitry 11 to thecommunication device 15, shown in FIG. 1. Consequently, the descriptionthereof is omitted.

The radiation irradiator 56 has a configuration equivalent to theconfiguration of the radiation irradiator 16 shown in FIG. 1. Theradiation irradiator 56 is a device that irradiates a patient withradiation under control of the processing circuitry 51. In the casewhere any of the radiation irradiating apparatuses 50 is an X-raydiagnostic apparatus, the radiation irradiator 56 of this radiationirradiating apparatus includes typical structures, such as a highvoltage generator, an X-ray source, an X-ray detector, and a bed. In thecase where any of the radiation irradiating apparatuses 50 is an X-rayCT apparatus, the radiation irradiator 56 of the radiation irradiatingapparatus includes typical structures, such as a high voltage generator,an X-ray source, an X-ray detector, a rotation unit, and a bed. In thecase where any of the radiation irradiating apparatuses is a radiationtherapeutic apparatus, the radiation irradiator 56 of this radiationirradiating apparatus includes typical structures, such as a highvoltage generator, a radiation source, a rotation unit, and a bed.

A set of FIGS. 17A and 17B is a block diagram showing functions of theradiation dose management system 30 according to the present embodiment.

The processing circuitry 41 included in the radiation dose managementsystem 30 according to the present embodiment executes the programs tothereby cause the radiation dose management apparatus 40 to function asa condition receiving function 411, a past cumulative dose distributionacquiring function 412, a past added dose distribution calculatingfunction 413, a past added dose distribution transmitting function 414,a cumulative dose distribution receiving function 415, and a cumulativedose distribution registering function 416. The description is madeassuming that the functions 411 to 416 function as software.Alternatively, all or some of the functions 411 to 416 may beimplemented as hardware in the radiation dose management apparatus 40.

The condition receiving function 411 receives the patient identifyinginformation (patient ID) that has been set by a specific radiationirradiating apparatus 50 a among the radiation irradiating apparatuses50 and transmitted from this apparatus 50 a.

The past cumulative dose distribution acquiring function 412 has afunction equivalent to that of the past cumulative dose distributionacquiring function 113 shown in FIG. 4. That is, the past cumulativedose distribution acquiring function 412 acquires (reads), from thecumulative dose distribution DB 47, the past cumulative dosedistributions associated with the patient identifying informationreceived by the condition receiving function 411. When the conditionreceiving function 411 sets the period condition, the past cumulativedose distribution acquiring function 412 acquires, from the cumulativedose distribution DB 47, the cumulative dose distributions associatedwith the patient identifying information received by the conditionreceiving function 411 and with the execution time information withinthe range of the period condition. Furthermore, when the conditionreceiving function 411 sets an apparatus condition, the past cumulativedose distribution acquiring function 412 acquires, from the cumulativedose distribution DB 47, the cumulative dose distributions associatedwith the patient identifying information received by the conditionreceiving function 411 and with the apparatus identifying informationencompassed by the apparatus condition.

The past added dose distribution calculating function 413 has a functionequivalent to that of the past added dose distribution calculatingfunction 114 shown in FIG. 4. That is, when the past cumulative dosedistributions are acquired by the past cumulative dose distributionacquiring function 412, the past added dose distribution calculatingfunction 413 aligns the past cumulative dose distributions and adds (ortotalizes) the distributions with respect to each body surface positionof the human body model, thereby calculating the data on the past addeddose distribution pertaining to the past radiation irradiatingmanipulations.

That is, when the past cumulative dose distributions are received by thepast cumulative dose distribution acquiring function 412, the past addeddose distribution calculating function 413 adds the past cumulativedoses with respect to each body surface position, thereby calculatingthe data on the past added dose distribution pertaining to the pastradiation irradiating manipulations. In the case where one pastcumulative dose distribution is acquired by the past cumulative dosedistribution acquiring function 412, the past added dose distributioncalculating function 413 is unnecessary. Here, the example of the dataon the past added dose distribution is equivalent to that shown in FIG.6.

Alternatively, the past added dose distribution calculating function 413may be included in each of the radiation irradiating apparatuses 50.

The past added dose distribution transmitting function 414 transmits thepast added dose distribution calculated by the past added dosedistribution calculating function 413, to the radiation irradiatingapparatus 50 a having transmitted the patient identifying information.

The cumulative dose distribution receiving function 415 receives thecumulative dose distribution that has been calculated by the radiationirradiating apparatus 50 a, which has transmitted the patientidentifying information, and been transmitted from this apparatus 50 a.

The cumulative dose distribution registering function 416 has a functionequivalent to that of the cumulative dose distribution registeringfunction 117 shown in FIG. 4. That is, after the radiation irradiatingmanipulation by the radiation irradiating apparatus 50 a is finished,the cumulative dose distribution registering function 416 assigns thepatient identifying information, the execution time information and theapparatus identifying information to the cumulative dose distribution(single cumulative dose distribution) calculated by the radiationirradiating apparatus 50 a, and registers the distribution in thecumulative dose distribution DB 47.

The processing circuitry 51 included in the radiation dose managementsystem 30 according to the present embodiment executes the programs tothereby cause each of the radiation irradiating apparatuses 50 tofunction as an operation assisting function 511, a condition settingfunction 512, a condition transmitting function 513, a past added dosedistribution receiving function 514, a radiation irradiation executingfunction 515, a sequential cumulative dose distribution calculatingfunction 516, and a cumulative dose distribution transmitting function517. The description is made assuming that the functions 511 to 517function as software. Alternatively, all or some of the functions 511 to517 may be implemented as hardware in each of the radiation irradiatingapparatuses 50.

The operation assisting function 511 has a function equivalent to theoperation assisting function 111 shown in FIG. 4. That is, the operationassisting function 511 functions as an interface, such as GUI, thatmediates the functions 512 to 517 and the operation device 53 and thedisplay 54.

The condition setting function 512 has a function equivalent to thecondition setting function 112 shown in FIG. 4. That is, the conditionsetting function 512 sets the patient identifying information (patientID) based on an operation at the operation device 53 through theoperation assisting function 511. The patient ID is used for acquiringthe past cumulative dose distributions pertaining to the patientsubjected to the radiation irradiating manipulation. In addition, thecondition setting function 512 may set a period condition for acquiringonly the cumulative dose distributions in a specific period and theapparatus condition for acquiring only the cumulative dose distributiongenerated through the radiation irradiating manipulation by the specificradiation irradiating apparatus, among the entire past cumulative dosedistributions pertaining to the patient subjected to the radiationirradiating manipulation.

The condition transmitting function 513 transmits the patientidentifying information set by the condition setting function 512 to thecondition receiving function 411 of the radiation dose managementapparatus 40.

The past added dose distribution receiving function 514 receives thepast added dose distribution transmitted from the past added dosedistribution transmitting function 414 of the radiation dose managementapparatus 40.

The radiation irradiation executing function 515 has a functionequivalent to that of the radiation irradiation executing function 115shown in FIG. 4. That is, the radiation irradiation executing function515 applies a radiation irradiating manipulation to the patientassociated with the patient identifying information set by the conditionsetting function 512. Here, in the case where any of the radiationirradiating apparatuses 50 is an X-ray diagnostic apparatus or an X-rayCT apparatus, the radiation irradiation executing function 515 of thisradiation irradiating apparatus controls the operation of the radiationirradiator 56 to collect an image pertaining to detection portion of thepatient while emitting radiation. In the case where any of the radiationirradiating apparatuses 50 is a radiation therapeutic apparatus, theradiation irradiation executing function 515 of this radiationirradiating apparatus controls the operation of the radiation irradiator56 to irradiate a therapy target portion of the patient.

The sequential cumulative dose distribution calculating function 516 hasa function equivalent to that of the sequential cumulative dosedistribution calculating function 116 shown in FIG. 4. That is, duringexecution of the radiation irradiating manipulation by the radiationirradiation executing function 515, the sequential cumulative dosedistribution calculating function 516 cumulates the exposure dose untilthe present time, thereby sequentially calculating the cumulative dose.The sequential cumulative dose distribution calculating function 516sequentially calculates the cumulative dose distribution that associatesthe cumulative doses with the body surface positions of the human bodymodel.

The body surface position of the patient in the real coordinate systemis coordinate-transformed into the corresponding body surface positionin the human body model in the model coordinate system. Thistransformation allows the cumulative dose pertaining to the body surfaceposition of the patient in the real coordinate system to be consideredas the cumulative dose on the corresponding body surface position of thehuman body model. The sequential cumulative dose distributioncalculating function 516 includes a single cumulative dose distributioncalculating function 516 a, and a total cumulative dose distributioncalculating function 516 b.

The single cumulative dose distribution calculating function 516 a has afunction equivalent to that of the single cumulative dose distributioncalculating function 116 a. That is, the single cumulative dosedistribution calculating function 516 a sequentially calculates, as thesingle cumulative dose distribution, the cumulative dose distributionfrom the start of the radiation irradiating manipulation under executionto the present time during execution of the radiation irradiatingmanipulation. The single cumulative dose distribution associates thecumulative doses from the start of the radiation irradiatingmanipulation under execution to the present time with the body surfacepositions of the human body model.

The total cumulative dose distribution calculating function 516 bsequentially adds the single cumulative dose distribution calculated bythe single cumulative dose distribution calculating function 516 a tothe past added dose distribution received by the past added dosedistribution receiving function 514, during execution of the radiationirradiating manipulation. The total cumulative dose distributioncalculating function 516 b sequentially calculates the total cumulativedose to the present time from the start of the radiation irradiatingmanipulation pertaining to the latest cumulative dose distribution amongthe past cumulative dose distributions. The total cumulative dosedistribution associates, with the body surface positions of the humanbody model, the total cumulative doses to the present time from thestart of the radiation irradiating manipulation pertaining to the latestcumulative dose distribution among the past cumulative dosedistributions.

When the one past cumulative dose distribution is acquired by the pastcumulative dose distribution acquiring function 412, the totalcumulative dose distribution calculating function 516 b sequentiallyadds the single cumulative dose distribution calculated by the singlecumulative dose distribution calculating function 516 a to one pastcumulative dose distribution during execution of the radiationirradiating manipulation. The total cumulative dose distributioncalculating function 516 b calculates the total cumulative dose to thepresent time from the start of the radiation irradiating manipulationpertaining to the one past cumulative dose distribution.

The sequential cumulative dose distribution calculating function 516sequentially displays, on the display 54 (corresponding to the display14 in FIG. 2), the single cumulative dose distribution and the totalcumulative dose distribution through the operation assisting function511 during execution of the radiation irradiating manipulation (FIGS. 8and 10 to 14). Alternatively, the sequential cumulative dosedistribution calculating function 516 switches between sequentialdisplay of the single cumulative dose distribution on the display 54through the operation assisting function 511 and the sequential displayof the total cumulative dose distribution on the display 54 through theoperation assisting function 511 during execution of the radiationirradiating manipulation (FIG. 9).

The cumulative dose distribution transmitting function 517 transmits,after the radiation irradiating manipulation by the radiationirradiation executing function 515 is finished, the cumulative dosedistribution (single cumulative dose distribution) calculated by thesingle cumulative dose distribution calculating function 516 a of thesequential cumulative dose distribution calculating function 516together with the patient identifying information, the execution timeinformation and the apparatus identifying information, to the cumulativedose distribution receiving function 415 of the radiation dosemanagement apparatus 40.

Subsequently, the operations of the radiation dose management system 30according to the present embodiment are described with reference toFIGS. 15 and 18.

A set of FIGS. 18A and 18B is a flowchart showing operations of theradiation dose management system 30 according to the present embodiment.

One radiation irradiating apparatus 50 a among the radiation irradiatingapparatuses 50 in the radiation dose management system 30 sets thepatient identifying information “Patient P1” for acquiring the pastcumulative dose distributions pertaining to the patient subjected to theradiation irradiating manipulation (step ST1). In addition, step ST1 mayset a period condition for acquiring only the cumulative dosedistributions in a specific period and the apparatus condition foracquiring only the cumulative dose distribution generated by theradiation irradiating manipulation by the specific radiation irradiatingapparatus, among all the past cumulative dose distributions pertainingto the patient subjected to the radiation irradiating manipulation.

The radiation irradiating apparatus 50 a transmits the patientidentifying information “Patient P1” set in step ST1 to the radiationdose management apparatus 40 (step ST2).

The radiation dose management apparatus 40 receives the patientidentifying information “Patient P1” transmitted in step ST2, andacquires the past cumulative dose distributions associated with thereceived patient identifying information “Patient P1” from thecumulative dose distribution DB 47 (shown in FIG. 16) (step ST3).

When the past cumulative dose distributions are acquired in step ST3,the radiation dose management apparatus 40 aligns and adds the pastcumulative dose distributions, thereby calculating the data on a pastadded dose distribution pertaining to the past radiation irradiatingmanipulations (step ST4).

The radiation dose management apparatus 40 transmits the past added dosedistribution calculated in step ST4 to radiation irradiating apparatus50 a (step ST5).

The radiation irradiating apparatus 50 a receives the past added dosedistribution transmitted in step ST5, and starts applying the radiationirradiating manipulation to the patient associated with the patientidentifying information “Patient P1” set in step ST1 (step ST6).

The radiation irradiating apparatus 50 a calculates the cumulative dosedistribution as the single cumulative dose distribution during executionof the radiation irradiating manipulation, and displays the distributionon the display 54 (step ST7). At the same time, the radiationirradiating apparatus 50 a adds the single cumulative dose distributioncalculated in step ST7 to the past added dose distribution received instep ST6 during execution of the radiation irradiating manipulation,thus calculating the total cumulative dose distribution and displayingthe calculated distribution on the display 54 (corresponding to display14 shown in FIG. 2) (step ST8). Display screens in steps ST7 and ST8 areshown in FIGS. 8 to 14.

The single cumulative dose distribution and the total cumulative dosedistribution in steps ST7 and ST8 are repeatedly displayed until theradiation irradiating manipulation under execution is finished.

After the radiation irradiating manipulation started in step ST6 isfinished, the radiation irradiating apparatus 50 a assigns the patientidentifying information, the execution time information and theapparatus identifying information to the cumulative dose distribution(single cumulative dose distribution) calculated in step ST7, andtransmits the distribution to the radiation dose management apparatus 40(step ST9).

The radiation dose management apparatus 40 receives the cumulative dosedistribution transmitted in step ST9, and registers the receivedcumulative dose distribution in the cumulative dose distribution DB 47(step ST10).

Next, at a timing after step ST1, another radiation irradiatingapparatus 50 b among the radiation irradiating apparatuses 50 in theradiation dose management system 30 sets the patient identifyinginformation “Patient P1” for acquiring the past cumulative dosedistributions pertaining to the patient subjected to the radiationirradiating manipulation (step ST11). In addition, step ST11 may set aperiod condition for acquiring only the cumulative dose distributions ina specific period among all the past cumulative dose distributionspertaining to the patient subjected to the radiation irradiatingmanipulation.

The radiation irradiating apparatus 50 b transmits the patientidentifying information “Patient P1” set in step ST11 to the radiationdose management apparatus 40 (step ST12).

The radiation dose management apparatus 40 receives the patientidentifying information “Patient P1” transmitted in step ST12, andacquires the past cumulative dose distributions associated with thereceived patient identifying information “Patient P1” from thecumulative dose distribution DB 47 (step ST13). Here, the patientidentifying information “Patient P1” received in step ST3 coincides withthe patient identifying information “Patient P1” received in step ST13.Consequently, the past cumulative dose distribution acquired in stepST13 contains the cumulative dose distribution registered in step ST10.

When multiple past cumulative dose distributions are acquired in stepST13, the radiation dose management apparatus 40 aligns and adds thepast cumulative dose distributions, thereby calculating the data on apast added dose distribution pertaining to the past radiationirradiating manipulations (step ST14).

The radiation dose management apparatus 40 transmits the past added dosedistribution calculated in step ST14 to radiation irradiating apparatus50 b (step ST15).

The radiation irradiating apparatus 50 b receives the past added dosedistribution transmitted in step ST15, and starts applying the radiationirradiating manipulation to the patient associated with the patientidentifying information “Patient P1” set in step ST11 (step ST16).

The radiation irradiating apparatus 50 b calculates the cumulative dosedistribution as the single cumulative dose distribution during executionof the radiation irradiating manipulation, and displays the distributionon the display 54 (step ST17). At the same time, the radiationirradiating apparatus 50 b adds the single cumulative dose distributioncalculated in step ST17 to the past added dose distribution received instep ST16 during execution of the radiation irradiating manipulation,thus calculating the total cumulative dose distribution and displayingthe calculated distribution on the display 54 (display 14 shown in FIG.2) (step ST18). Display screens in steps ST17 and ST18 are shown inFIGS. 8 to 14.

The single cumulative dose distribution and the total cumulative dosedistribution in steps ST17 and ST18 are repeatedly displayed until theradiation irradiating manipulation under execution is finished.

After the radiation irradiating manipulation started in step ST16 isfinished, the radiation irradiating apparatus 50 b assigns the patientidentifying information, the execution time information and theapparatus identifying information to the cumulative dose distribution(single cumulative dose distribution) calculated in step ST17, andtransmits the distribution to the radiation dose management apparatus 40(step ST19).

The radiation dose management apparatus 40 receives the cumulative dosedistribution transmitted in step ST19, and registers the receivedcumulative dose distribution in the cumulative dose distribution DB 47(step ST20).

The radiation dose management system 30 according to the presentembodiment effectively displays, on the display 54, at least one of thesingle cumulative dose distribution and the total cumulative dosedistribution during application of the radiation irradiatingmanipulation to the patient, thereby allowing the operator, who is amedical doctor or a medical technician, to easily monitor the singlecumulative dose distribution and the total cumulative dose distributionpertaining to the patient during the application of the radiationirradiating manipulation to the patient.

The radiation dose management system 30 according to the presentembodiment effectively displays, on the display 54, at least one of thesingle cumulative dose distribution and the total cumulative dosedistribution during application of the radiation irradiatingmanipulation to the patient, thereby allowing the operator to easilydetermine an appropriate radiation irradiating direction so as toprevent portions having been irradiated with radiation from beingfurther irradiated, during the application of the radiation irradiatingmanipulation to the patient. Consequently, the radiation damage to thepatient can be alleviated. The radiation dose management system 30according to the present embodiment allows the operator to perform theradiation irradiating manipulation while verifying whether theapplication of the radiation during their radiation irradiatingmanipulation to the patient is appropriate or not through the display54.

While certain embodiments have been described, these embodiments havebeen presented by way of example only, and are not intended to limit thescope of the inventions. Indeed, the novel methods and systems describedherein may be embodied in a variety of other forms; furthermore, variousomissions, substitutions and changes in the form of the methods andsystems described herein may be made without departing from the spiritof the inventions. The accompanying claims and their equivalents areintended to cover such forms or modifications as would fall within thescope and spirit of the inventions.

What is claimed is:
 1. A radiation irradiating apparatus comprising a processing circuitry configured to: acquire a past cumulative dose distribution associated with patient identifying information, from a storage that is storable a cumulative dose distribution; calculate a first cumulative dose distribution and a second cumulative dose distribution during a radiation irradiation to a patient associated with the patient identifying information, the first cumulative dose distribution being a cumulative dose distribution, the second cumulative dose distribution being generated by adding the first cumulative dose distribution to the past cumulative dose distribution; and display, on a display, at least one of the first and second cumulative dose distributions during the radiation irradiation.
 2. The radiation irradiating apparatus according to claim 1, wherein the radiation is X-rays, and the processing circuitry is configured to: sequentially generate each of fluoroscopic images based on the X-rays having passed through the patient; and sequentially display, on the display, a distribution to be displayed that is at least one of the first and second cumulative dose distributions, and display, on the display, the fluoroscopic images as a moving image.
 3. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to register the first cumulative dose distribution in the storage.
 4. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to: align, when a plurality of past cumulative dose distributions are acquired as the past cumulative dose distribution, the past cumulative dose distributions, and add the aligned distributions with respect to body surface positions of a human body model to calculate a past added dose distribution; and add the first cumulative dose distribution to the past added dose distribution during the radiation irradiation to calculate the second cumulative dose distribution.
 5. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to display the first and second cumulative dose distributions in a juxtaposed manner.
 6. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to switchably display, on the display, the first and second cumulative dose distributions.
 7. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to zoom in and display one of the first and second cumulative dose distributions, while zooming out and displaying the other distribution.
 8. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to sequentially and entirely display, on the display, one of the first and second cumulative dose distributions, while sequentially and partially displaying the other distribution on the display.
 9. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to sequentially display, on the display, one of the first and second cumulative dose distributions in a shaded manner, while sequentially displaying the other distribution on the display in a numeric value.
 10. The radiation irradiating apparatus according to claim 1, wherein the processing circuitry is configured to sequentially display, on the display, the first and second cumulative dose distributions in different display patterns in an overlaid manner.
 11. A radiation dose management system comprising a processing circuitry configured to: acquire a past cumulative dose distribution associated with required patient identifying information, from a storage that is storable a plurality of cumulative dose distributions by a plurality of radiation irradiating apparatuses performing radiation irradiations; calculate a first cumulative dose distribution and a second cumulative dose distribution during a radiation irradiation to a patient associated with the required patient identifying information, the first cumulative dose distribution being a cumulative dose distribution, the second cumulative dose distribution being generated by adding the first cumulative dose distribution to the past cumulative dose distribution; and display, on a display, at least one of the first and second cumulative dose distributions during the radiation irradiation. 